JP3578238B2 - Silicon wafer processing method - Google Patents

Description

【００１７】
表１から明らかなように、比較例１のシリコンウェーハは高い平坦度を示したが、両面が同じように光沢度に優れたため表裏の区別が付かなかった。また比較例２のシリコンウェーハは表裏の区別は容易に付いたが、平坦度に劣っていた。これらに対して実施例１のシリコンウェーハは比較例１（両面研磨）のシリコンウェーハと同程度の高い光沢度と、比較例２（片面研磨）のシリコンウェーハと同様に表裏の区別が容易に付いた。
【００１８】
【発明の効果】
以上述べたように、本発明によれば、両面同時研磨の後にウェーハ裏面を化学エッチングで曇化し、この化学エッチングを、両面が鏡面加工されたシリコンウェーハの片面をこの片面全体に密着可能であって化学エッチングのエッチング液に対して疎水性のある台板に真空吸着により密着してこの台板により被覆した後、ウェーハの別の片面をエッチングすることにより行うことにより、極めて高い平坦度を有し、かつ光沢度の差による表裏を容易に区別可能なシリコンウェーハが得られる。この結果、２５６Ｍ ＤＲＡＭ以上の高い記憶容量のメモリを有するデバイスに適するシリコンウェーハが得られる。また両面同時研磨法で加工するため、研磨時の接着剤を除去する煩わしさがなく、そりが小さい利点もある。
【図面の簡単な説明】
【図１】本発明のシリコンウェーハの加工方法を示す工程図。
【図２】両面同時研磨した後にウェーハ裏面を曇化する固定式エッチング法を示す図。（ａ）第２化学エッチング液によりウェーハ裏面をエッチングしている状況を示す断面図。
（ｂ）エッチングしたウェーハ裏面を純水で洗浄している状況を示す断面図。
【図３】ステッパによる露光領域における焦点面からのポジティブ最大偏差ａとネガティブ最大偏差ｂとによりローカルサイト平坦度を示す図。
【符号の説明】
１０ シリコンウェーハ
１１ 台板
１２ 容器
１３ 筒
１４ 酸エッチング液 [0001]
TECHNICAL FIELD OF THE INVENTION
The present invention is single-side mirror-polished flatness on Machining method extremely high silicon-way Ha. And more particularly to a silicon processing method Kwai Ha suitable for devices having a memory of high storage capacity of more than 256M DRAM.
[0002]
[Prior art]
Generally, the surface processing shape and accuracy required for a silicon wafer are governed by the minimum line width (design rule) of a circuit pattern corresponding to the degree of integration of a device. The required flatness also depends on the exposure apparatus used in the lithography process during device manufacture. Therefore, it is necessary to achieve flatness equal to or less than the design rule in a region corresponding to the exposure area.
In order to obtain the desired flatness, a wafer cut from a silicon single crystal ingot is mechanically polished, and the polished wafer is chemically etched, and then only one side of the wafer is mechanically and chemically polished. A mirror finishing method is employed. In this single-side polishing method, several silicon wafers are adhered to a polishing block with wax or the like, and an appropriate pressure is applied to artificial leather (polishing cloth) in which the block is adhered on a rotary table to adjust the pH to 9 with SiO ₂ as a main component. In this method, only one side of the wafer is polished while supplying about ~ 12 alkaline colloidal silica polishing liquid.
[0003]
However, in this method, the pressure on the wafer attached to the polishing block during single-side polishing transfers fine irregularities on the surface of the polishing block to the back surface of the wafer, and when the wafer is removed from the polishing block after polishing, the shape of the back surface of the wafer is changed. Transfer to the polished surface of the wafer surface. Alternatively, the roughness of the back surface of the wafer generated by the chemical etching process has an adverse effect on the polished surface after polishing. For this reason, in the case of a single-sided mirror-finished wafer, TTV (total thickness variation) representing the difference between the maximum value and the minimum value of the wafer surface height when the wafer is suction-fixed among the flatness values is a relatively good value. As shown, there was a problem that the local-site flatness representing the site flatness based on the surface was not so good. In addition, the single-side polished wafer has a disadvantage that a relatively large warp is inevitably caused by the heat treatment, and has a trouble that the back surface of the wafer contaminated with the bonding wax must be cleaned.
The mirror-finished silicon wafer is mainly used directly as a substrate for various ICs such as VLSI or a substrate for an epitaxial wafer because of its high flatness. In recent years, demands for quality, particularly flatness, of silicon wafers have been increasing strictly in response to higher integration and higher density of devices. To satisfy this requirement, a double-sided simultaneous polishing method has been proposed instead of the single-sided polishing method. According to this method, while loading and maintaining a silicon wafer in a wafer receiving hole of a carrier plate that is slightly thinner than its finished thickness, an upper platen and a lower platen which rotate the front and back surfaces of the silicon wafer in opposite directions through a polishing cloth. This is a method of mechanically and chemically polishing. In this method, the wafer is not bonded to any of the surface plates, and the upper and lower surface plates are constantly changed in contact position with the wafer during polishing, so that the above-mentioned problem of the single-side polishing method can be solved.
[0004]
[Problems to be solved by the invention]
In other words, as described above, a silicon wafer having a desired flatness with respect to the site flatness or TTV was stably obtained with the double-sided mirror-finished product by the double-sided simultaneous polishing method, but with the conventional single-sided mirror-finished product. It was difficult to obtain it stably. On the other hand, in the case of a double-sided mirror-finished product, it is difficult to distinguish between the front and back of the wafer because both sides of the wafer have exactly the same mirror surface and the same gloss, and since the light reflectance of the surface corresponding to the upper and lower surfaces is high, it is provided on a stepper. It is difficult for the sensor to recognize the wafer due to an error in a normal setting.
An object of the present invention is to provide a very high has a flatness, and the silicon processing method Kwai Ha distinction between front and back due to the difference in glossiness can be facilitated.
Another object of the present invention without the inconvenience of removing the adhesive during polishing is to provide a method for processing a warping small silicon-way Ha.
[0005]
[Means for Solving the Problems]
According to the first aspect of the present invention, one surface of a mirror-finished silicon wafer having a site flatness of 0.01 to 0.1 μm (PUA 95% or more) and a TTV of 1.0 μm or less is fogged by chemical etching. it is an improvement of the processing method Cie silicon wafer. The characteristic configuration is that in chemical etching, one side of a silicon wafer whose both sides are mirror-finished can be adhered to this entire surface and adhered to the base plate that is hydrophobic to the etchant of chemical etching by vacuum suction. After coating with a lever plate, another side of the wafer is etched.
However, the site flatness refers to the center of the site at each site on the wafer surface, which is a unit exposure area that is a unit exposure area obtained by dividing the entire surface of the wafer into a certain size by a stepper, using the back surface of the wafer, which is a plane formed by vacuum suction-fixing a silicon wafer, as a reference surface. When a plane including a point is defined as a focal plane, the maximum displacement amount not including a sign from the focal plane in the site. The site flatness of 0.01 to 0.1 μm (PUA 95% or more) means that 95 % Or more means having a site flatness of 0.01 to 0.1 μm. TTV refers to the difference between the maximum value and the minimum value of the wafer surface height from the reference surface, which is the back surface of the wafer, which is a plane formed by vacuum-suction-fixing the silicon wafer.
Since both surfaces of the wafer are mirror-finished and then only the back surface is clouded, the wafer surface has extremely high flatness, while the difference in glossiness from the back surface is significant, and the front and back of the wafer can be easily distinguished.
[0006]
Here, PUA is an abbreviation of Percent Usable Area and refers to a percentage of an area satisfying a prescribed level. Specifically, the site flatness is measured by a thickness measuring device having a capacitance type sensor, and is referred to as SFPD (Site Focal Plane Deviation). This SFPD is the maximum displacement amount that does not include the sign from the focal plane within the site, when the back surface of the wafer is used as the reference plane and the plane including the site center point at each site is used as the focal plane. PUA 95% or more means that 95% or more of the divided areas have a site flatness of 0.01 to 0.1 μm. By setting the site flatness of the surface of the silicon wafer to 0.01 to 0.1 μm (PUA 95% or more) or setting the TTV to 1.0 μm or less, the flatness of the mirror-finished wafer can be extremely increased. On the other hand, since the back surface of the wafer is a non-mirror surface, the glossiness of the front and back surfaces has a remarkable difference, so that the front and back surfaces of the wafer can be easily distinguished.
[0008]
In the chemical etching of the present invention, one side of the wafer is closely adhered to the base plate by a method such as vacuum suction and covered with the base plate, so that the etching of the adhered surface is prevented, and only the other side is etched. become.
[0009]
BEST MODE FOR CARRYING OUT THE INVENTION
The silicon wafer of the present invention is obtained by the processing method according to claim 1 . As an example of this method, there is the following processing method. That is, after the grown single crystal ingot is cut into blocks having a certain resistivity range, each block is subjected to outer diameter grinding in order to make the diameter uniform. Thereafter, an orientation flat or notch is applied to the block whose outer diameter has been ground to indicate a specific crystal orientation.
After cutting (slicing) and chamfering (beveling) the silicon wafer from the block, the silicon wafer is mechanically polished (lapping) as shown in FIG. This lapping method is a method in which a lapping liquid, which is a mixture of alumina or silicon carbide abrasive grains and glycerin, is poured between a lapping plate and a wafer, and the both sides of the wafer are mechanically polished by rotating and sliding under pressure. Due to this lapping, the uneven layer on both surfaces of the wafer, which is mainly caused by slicing, is scraped off, and the flatness of the surface and the parallelism of the wafer are increased.
[0010]
A silicon wafer that has been subjected to machining processes such as block cutting, outer diameter grinding, slicing, and lapping has a damaged layer, that is, a damaged layer on both surfaces. As shown in FIG. 1B, after lapping, the silicon wafer is subjected to a first chemical etching to remove the affected layer. The etching solution (etchant) includes an acid etching solution or an alkali etching solution. The former is a three-component etching solution obtained by diluting a mixed acid of hydrofluoric acid (HF) and nitric acid (HNO ₃ ) with water (H ₂ O) or acetic acid (CH ₃ COOH). Si is oxidized by nitric acid to form SiO ₂ Is generated, this SiO ₂ is dissolved and removed by hydrofluoric acid. The latter is an etching solution obtained by diluting KOH or NaOH with water. In addition, at the time of this chemical etching, a grinding process can be performed in order to further reduce the affected layer.
After the first chemically etched silicon wafer is subjected to an external gettering process for removing a metal that adversely affects device characteristics and a heat treatment for erasing oxygen donors, both surfaces thereof are simultaneously polished as shown in FIG. Is done. This double-sided simultaneous polishing method is the same as the method described in the prior art, in which the front and back surfaces of the silicon wafer are loaded while maintaining the silicon wafer in the wafer receiving hole of the carrier plate slightly thinner than its finished thickness. This is a method of mechanically and chemically polishing by an upper surface plate and a lower surface plate that rotate in opposite directions via a polishing cloth.
The double-sided mirror finishing of the silicon wafer of the present invention is not limited to the above-described method, and can be obtained by, for example, grinding both sides of the wafer after slicing or lapping.
[0011]
Next, as shown in FIG. 1D, the silicon wafer polished on both sides at the same time is clouded on the back surface of the wafer by the second chemical etching. This etching how are etchant stationary manner shown in FIG. In the etchant-fixed method, a base plate that has a larger area than both sides of a mirror-finished silicon wafer and can adhere to one side of the wafer and is hydrophobic with respect to the etchant is prepared. After coating one side, this is a method of etching only another side of this wafer. As the etchant for the second chemical etching, an acid etchant having an etching rate of 7 to 100 μm / min, a surface tension of at least 60 dyne / cm, and a viscosity of 1.4 to 4.5 mPa · sec. Alkaline etchants are mentioned. To illustrate an acid etchant, HF (50%): HNO ₃ (70%): H ₃ PO ₄ (85%): H ₂ O = 2: 1: 1: 1 or 2: 1: 1: 1.5, or HF (50%): HNO ₃ (70%): H ₃ PO ₄ (85%) = 2: 1: 1. As the base plate, for example, there is a base plate made of polytetrafluoroethylene. If the wafer is brought into close contact with the base plate by a method such as vacuum suction, the etchant does not enter the contact surface.
[0012]
【Example】
Next, examples of the present invention will be described in detail with reference to the drawings together with comparative examples.
<Example 1>
Through the steps described in the embodiment of the invention based on FIGS. 1A to 1C, a silicon single crystal ingot pulled up by the CZ method is simultaneously polished on both sides at the same time, and has a diameter of 200 mm and a thickness of 730 μm. A wafer was obtained. Here, an acid etching solution was used for the first chemical etching. The back surface of the double-side polished wafer was clouded by the second chemical etching as shown in FIG. 1 (d) and FIG. That is, as shown in FIG. 2A, a base plate 11 made of polytetrafluoroethylene (trade name: Teflon) having an extremely smooth surface having a larger area than the silicon wafer 10 and having hydrophobicity with respect to an etchant is placed in a container. 12, and the wafer 10 was placed on the center of the base plate 11 such that the back surface of the wafer was in close contact.
Next, a cylinder 13 made of polytetrafluoroethylene (trade name: Teflon) having an inner diameter larger than the outer diameter of the wafer 10 was placed on the base plate 11 so as to surround the wafer 10. An acid at 25 ° C. mixed in the tube 13 at a ratio of HF (50%): HNO ₃ (70%): H ₃ PO ₄ (90%): H ₂ O = 2: 1: 1: 1.5 The etching solution 14 was gently injected. After the acid etching solution 14 is left on the wafer 10 for 60 seconds, the cylinder 13 is removed and a large amount of pure water is put into the container 12 as shown in FIG. Was stopped and the wafer surface was cleaned. Next, the wafer 10 was taken out of the container 12 together with the base plate 11, and the wafer 10 was peeled off from the base plate 11 and dried to obtain a silicon wafer whose back surface was clouded. The etching depth was about 10 μm.
[0013]
<Comparative Example 1>
Comparative Example 1 was a double-side polished silicon wafer which was the same as Example 1 except that the back surface of the wafer was not clouded.
[0014]
<Comparative Example 2>
The silicon wafer of Comparative Example 2 used the same process as that of Example 1 up to the double-sided simultaneous polishing of Example 1. That is, instead of the simultaneous double-side polishing in Example 1, 16 silicon wafers were attached to a polishing block with wax, and an appropriate pressure was applied to artificial leather (polishing cloth) in which the block was bonded on a rotary table to form SiO _2. Only one side of the wafer was polished while supplying an alkaline colloidal silica polishing solution having a pH of about 9 to 12 as a main component.
[0015]
<Comparison test>
The glossiness, TTV, and site flatness (SPPD) of the single-side frosted wafer of Example 1, the double-side polished wafer of Comparative Example 1, and the single-side polished wafer of Comparative Example 2 were examined. Table 1 shows the results.
(A) Gloss After both sides of each silicon wafer were visually observed, the gloss was measured with a gloss meter manufactured by Nippon Denshoku Co., Ltd. according to a gloss 60 ° standard.
(B) TTV
After each silicon wafer was fixed by suction, the difference between the maximum value and the minimum value of the wafer surface height was determined, and the value was defined as TTV.
(C) SFPD
The back surface of each wafer was vacuum-sucked on a vacuum suction board, and in this state, the local site flatness of a unit exposure area of 25 mm × 25 mm was obtained by a stepper as shown in FIG. That is, all points in each wafer surface were determined based on a plane calculated by the least squares method, and the maximum absolute displacement from this reference plane (best-fit reference plane) was determined as SFPD.
[0016]
[Table 1]

[0017]
As is evident from Table 1, the silicon wafer of Comparative Example 1 showed high flatness, but the front and back sides could not be distinguished because both surfaces were similarly excellent in glossiness. Further, the silicon wafer of Comparative Example 2 was easily distinguished from the front and back, but was inferior in flatness. On the other hand, the silicon wafer of Example 1 has the same high gloss as the silicon wafer of Comparative Example 1 (double-side polishing), and the front and back can be easily distinguished similarly to the silicon wafer of Comparative Example 2 (single-side polishing). Was.
[0018]
【The invention's effect】
As described above, according to the present invention, the backside of the wafer is clouded by chemical etching after the simultaneous polishing of both sides , and this chemical etching can be brought into close contact with one side of the silicon wafer whose both sides are mirror-finished. After being adhered to a base plate that is hydrophobic to the etchant of chemical etching by vacuum suction and covered with this base plate, by etching another side of the wafer , extremely high flatness is achieved. A silicon wafer having the same and having a gloss difference that can easily distinguish the front and back sides can be obtained. As a result, a silicon wafer suitable for a device having a memory having a high storage capacity of 256M DRAM or more can be obtained. In addition, since the polishing is performed by the double-sided simultaneous polishing method, there is no trouble in removing the adhesive at the time of polishing, and there is an advantage that warpage is small.
[Brief description of the drawings]
FIG. 1 is a process chart showing a method for processing a silicon wafer according to the present invention.
FIG. 2 is a view showing a fixed etching method for clouding the back surface of a wafer after simultaneous polishing of both surfaces. (A) Sectional drawing which shows the situation which is etching the back surface of a wafer with 2nd chemical etching liquid.
(B) Sectional drawing which shows the state which wash | cleans the back surface of the etched wafer with pure water.
FIG. 3 is a diagram showing local site flatness based on a positive maximum deviation a and a negative maximum deviation b from a focal plane in an exposure area by a stepper.
[Explanation of symbols]
Reference Signs List 10 silicon wafer 11 base plate 12 container 13 cylinder 14 acid etching solution

Claims (1)

A method of processing a silicon wafer in which one side of a mirror-finished silicon wafer having a site flatness of 0.01 to 0.1 μm (PUA 95% or more) and a TTV of 1.0 μm or less is fogged by chemical etching on both sides ,
In the chemical etching, one surface of a silicon wafer whose both surfaces are mirror-finished can be adhered to the entire one surface, and the silicon wafer is adhered by vacuum suction to a base plate which is hydrophobic with respect to the etching solution of the chemical etching, and the base plate And then etching another side of the wafer after coating with the silicon wafer.
However, the site flatness refers to the center of the site at each site on the wafer surface, which is a unit exposure area that is a unit exposure area obtained by dividing the entire surface of the wafer into a certain size by a stepper, using the back surface of the wafer, which is a plane formed by vacuum-suction-fixing the silicon wafer, as a reference When a plane including a point is defined as a focal plane, the maximum displacement amount not including a sign from the focal plane in the site. The site flatness of 0.01 to 0.1 μm (PUA 95% or more) means that 95 % Or more means having a site flatness of 0.01 to 0.1 μm. TTV refers to the difference between the maximum value and the minimum value of the wafer surface height from the reference surface, which is the back surface of the wafer, which is a plane formed by vacuum-suction-fixing the silicon wafer.

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